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一种用于智能监测工业废水中污染物的新型机器学习驱动的纳米膜传感器。

A Novel ML-Powered Nanomembrane Sensor for Smart Monitoring of Pollutants in Industrial Wastewater.

作者信息

Cavaliere Gabriele, Tari Luca, Siconolfi Francesco, Rehman Hamza, Kuzhir Polina, Maffucci Antonio, Ferrigno Luigi

机构信息

Department of Information and Electrical Engineering and Applied Mathematics, University of Salerno, 84084 Fisciano, Italy.

Department of Electrical and Information Engineering, University of Cassino and Southern Lazio, 03043 Cassino, Italy.

出版信息

Sensors (Basel). 2025 Sep 1;25(17):5390. doi: 10.3390/s25175390.

DOI:10.3390/s25175390
PMID:40942817
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12431498/
Abstract

This study presents a comprehensive analysis aimed at validating the use of an innovative nanosensor based on graphitic nanomembranes for the smart monitoring of industrial wastewater. The validation of the potential of the nanosensor was carried out through the development of advanced analytical methodologies, a direct experimental comparison with commercially available electrode sensors commonly used for the detection of chemical species, and the evaluation of performance under conditions very similar to real-world field applications. The investigation involved a series of controlled experiments using an organic pollutant-benzoquinone-at varying concentrations. Initially, data analysis was performed using classical linear regression models, representing a conventional approach in chemical analysis. Subsequently, a more advanced methodology was implemented, incorporating machine-learning techniques to train a classifier capable of detecting the presence of pollutants in water samples. The study builds upon an experimental protocol previously developed by the authors for the nanomembranes, based on electrochemical impedance spectroscopy. The results clearly demonstrate that integrating the nanosensor with machine-learning algorithms yields significant performance. The intrinsic properties of the nanosensor make it well-suited for potential integration into field-deployable platforms, offering a real-time, cost-effective, and high-performance solution for the detection and quantification of contaminants in wastewater. These features position the nanomembrane-based sensor as a promising alternative to overcome current technological limitations in this domain.

摘要

本研究进行了全面分析,旨在验证一种基于石墨纳米膜的创新型纳米传感器用于工业废水智能监测的可行性。通过开发先进的分析方法、与常用于检测化学物质的市售电极传感器进行直接实验比较以及在与实际现场应用非常相似的条件下评估性能,对纳米传感器的潜力进行了验证。该研究涉及一系列使用不同浓度有机污染物苯醌的对照实验。最初,使用经典线性回归模型进行数据分析,这是化学分析中的传统方法。随后,实施了一种更先进的方法,纳入机器学习技术来训练一个能够检测水样中污染物存在的分类器。该研究基于作者先前为纳米膜开发的基于电化学阻抗谱的实验方案。结果清楚地表明,将纳米传感器与机器学习算法相结合可产生显著的性能。纳米传感器的固有特性使其非常适合潜在地集成到现场可部署平台中,为废水中污染物的检测和定量提供实时、经济高效且高性能的解决方案。这些特性使基于纳米膜的传感器成为克服该领域当前技术限制的有前途的替代方案。

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